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Muataz I Dobouni
UD08978SEN15826
Sustainability in EIA study
Utilizing GIS in EIA Scoping
Atlantic International University
Honolulu, Hawaii
Fall 2009
Table of Contents
LIST OF ACRONYMS.........................................................................................................................3
1. INTRODUCTION.......................................................................................................................4
2. DESCRIPTION...........................................................................................................................5
3. GENERAL ANALYSIS..........................................................................................................................9
3.1 The Incorporation of GIS in the EIA System…………………………………………………….9
4. ACTUALISATION ‐ CASE STUDY......................................................................................................11
5. DISCUSSION ........................................................................................................................... 15
6. GENERAL RECOMMENDATION................................................................................................16
7. CONCLUSION.......................................................................................................................... 17
REFERENCES.................................................................................................................................... 19
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1- Introduction
In the past two decades, since the first legal requirements for scoping of
environmental impacts were promulgated, scoping requirements have become
commonplace. The requirement for scoping came as a response to the mounting
criticism of early EISs in the U.S. (Black,1981). The main argument for the
promulgation of scoping was to focus the EIS on the important decision making
issues. Since the Council on Environmental Quality (CEQ) regulations requiring
scoping first came into effect the idea of impact scoping spread quickly, and the
scoping stage become an integral part of the EIA process (ECE,1987). Moreover,
it is increasingly recognized that the effectiveness and quality of the entire EIA
process depends primarily on the scoping stage (Kennedy & Ross, 1992). Unless
accurate, quick and low cost scoping is carried out, one of two possible errors
are likely to adversely affect the process. The first is that much effort will be
wasted on analysis of issues which are later found to have no consequential
impact or are unimportant from a decision making point of view. The second
possible error occurs when an important environmental element is overlooked,
and thus not incorporated into the EIA.
Since scoping is carried out at the beginning of the EIA process, and since
impact evaluation cannot begin before completion of the scoping stage, scoping
is usually carried out under stringent time and budget constraints. As a result,
scoping must fulfill two contradictory requirements: good scoping must be
comprehensive and complete, while on the other hand, it must be performed
within a short time and with limited resources (ECE, 1991). This contradiction
determines the range and choice of scoping techniques.
Since EIA was first introduced in the NEPA legislation, many EIA techniques
have been developed. Twelve years ago a United Nation Economic and Social
Commission for Asia and the Pacific report (ESCAP, 1985) referred to over 100
different techniques for carrying out and implementing the entire EIA process. As
a result, many techniques encapsulate a scoping method - either implicitly or
(less common) explicitly. Most existing EIA/scoping techniques (such as
matrices, checklists, networks and so on) are not explicitly spatial, that is, they
are not based on geographic data bases and often do not make use of explicit
geographical data. The only spatial technique that is widely used in EIA is the
overlay technique developed by Ian McHarg some thirty years ago (McHarg,
1969). One reason for this gap is that spatial analysis was considered complex
and data hungry, requiring substantial time and money resources (Munn, 1975).
Consequently, spatial analysis was used primarily in the advanced stages of the
EIA process and not for impact scoping.
In recent years two important developments have reduced the complexity and
cost of spatial analysis. Firstly, the advent of user-friendly geographic information
systems (GISs); and secondly, the improved quality and wider availability of
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spatial data sets. Consequently, such sets are now adequate for routine analysis
(Batty, 1993).
Recent surveys of the use of GIS in EIA found that while GIS is widely utilized, its
use is largely limited to the basic GIS functions such as map production, classic
overlay or buffering (Joao, 1998). This utilization does not make full use of the
spatial analysis and modeling capabilities of GIS (Joao & Fonseca, 1996).
Noteworthy are some more complex, though sporadic reports on the uses of GIS
for EIA - such as using GIS in complex modeling representation techniques
(Schaller, 1990), or its potential as a repository for data and cumulative impact
assessment (Scott & Saulnier, 1993).
One factor that limits the usefulness of many existing EIA techniques is their
tendency to be monolithic - they advance a method for conducting the entire EIA
process and must be followed throughout the EIA life cycle from initiation to EIS
publication. Moreover, such techniques usually apply to a limited set of projects,
and to the attributes of a specific EIA system. In a critique of these techniques
(Lee 1988) asserts that many of them are not truly comprehensive, and that they
fail to deal properly with all stages of the EIA. Consequently, he suggests that
there is a need to use the “Tool box” approach, whereby a collection of methods
and techniques are made available for each stage of the EIA. By doing so, the
EIA analyst can choose the appropriate technique for the local circumstances
(Lee, 1988). This suggestion is commensurate with the general trend from
monolithic models to partial models, thus enabling better solutions to be found for
local problems (Batty,1993).
The shift to a “tool box” approach requires that specific techniques suited for the
scoping stage be identified and developed. Such techniques should allow the
main effects to be identified (though not necessarily quantified) quickly,
inexpensively, and often based on incomplete information.
The first question addressed in this paper is to what extent GIS can serve as a
basis for such techniques. This question, however, is not merely a technical one.
The use of GIS requires constant maintenance and incurs costs, therefore, the
second and central question that this paper addresses is what are the
institutional requirements for the effective use of GIS in the scoping stage.
These questions will be addressed in this paper by first describing and evaluates
a GIS based method proposed for scoping environmental impacts.
2- Description
2.1 SCOPING IN EIA SYSTEMS: A CLASSIFICATION
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